A robot apparatus includes a clamp mechanism; a transport mechanism; and a control unit. The clamp mechanism includes a first finger that has a first support surface and a housing portion and a second finger. The first support surface supports an aligned wire group that includes a plurality of wires, the housing portion includes a guide wall that is connected to the first support surface and regulates an amount of movement of the band member in a width direction. The second finger has a second support surface facing the first support surface and a facing portion being connected to the second support surface and facing the housing portion. The transport mechanism is capable of moving the clamp mechanism. The control unit controls a grip force of the clamp mechanism and a direction of movement of the clamp mechanism by the transport mechanism.

A robot apparatus includes a clamp mechanism; a transport mechanism; and a control unit. The clamp mechanism includes a first finger that has a first support surface and a housing portion and a second finger. The first support surface supports an aligned wire group that includes a plurality of wires, the housing portion includes a guide wall that is connected to the first support surface and regulates an amount of movement of the band member in a width direction. The second finger has a second support surface facing the first support surface and a facing portion being connected to the second support surface and facing the housing portion. The transport mechanism is capable of moving the clamp mechanism. The control unit controls a grip force of the clamp mechanism and a direction of movement of the clamp mechanism by the transport mechanism.

A robot hand module includes a palm part and a thumb module coupled to the palm part. The thumb module includes a thumb phalangeal part movably coupled to the palm part, a thumb cable part having a first side connected to the thumb phalangeal part, and a thumb driving part connected to a second side of the thumb cable part and configured to operate the thumb phalangeal part by extending the thumb cable part to the outside or retracting the thumb cable part. The thumb cable part includes a first thumb cable extended from the thumb driving part and having a first side fixed in the thumb phalangeal part and a second thumb cable having a first side and a second side fixed in the thumb phalangeal part.

Methods, systems, and methods of manufacture for soft robotic actuators are described herein. In one aspect, a soft robotic actuator can include an elastomeric material defining a cavity; a volume of liquid metal (LM) positioned within the cavity; and an energy source coupled to the LM, where the energy source is adapted or configured to alter a temperature of the volume of LM, whereby altering the temperature of the volume of LM initiates an actuation of the elastomeric material.

Methods, systems, and methods of manufacture for soft robotic actuators are described herein. In one aspect, a soft robotic actuator can include an elastomeric material defining a cavity; a volume of liquid metal (LM) positioned within the cavity; and an energy source coupled to the LM, where the energy source is adapted or configured to alter a temperature of the volume of LM, whereby altering the temperature of the volume of LM initiates an actuation of the elastomeric material.

Gripper mechanism (1) comprising a stator (2) and a pair of mobile grippers moveably coupled to the stator (2) via a linear bearing (8), the stator comprising a housing (4) and a permanent magnet (3) mounted within the housing (4), the mobile gripper (19) comprising a support portion (9), a coil (11) mounted on the support portion (9), and a gripper finger (10) coupled to the support portion (9), the coil (11) configured to generate a magnetic field in opposition to a magnetic field of the permanent magnet (3) to actuate displacement of the mobile gripper relative to the stator. The gripper mechanism further comprises at least one magnetic locking mechanism (7) comprising at least a first permanent magnet (18) mounted on one of the stator (2) and the mobile grippers (19), and a complementary soft magnetic material portion or magnet mounted on the other of the stator (2) and the mobile grippers (19) configured to magnetically lock the mobile grippers in at least one of a closed or opened position of the mobile grippers (19).

An affordance is disclosed which allows a robot system to pick an expanded range of items using a single type of end effector, without requiring the use of different end effectors. The affordance includes a first layer and a second layer. The first layer is arranged to be grasped by an end effector of the robot system and the second layer is arranged to adhere to the item. A system having an affordance and a robot system with an end effector arranged to grasp at least one item from storage by way of the affordance is also disclosed.

An affordance is disclosed which allows a robot system to pick an expanded range of items using a single type of end effector, without requiring the use of different end effectors. The affordance includes a first layer and a second layer. The first layer is arranged to be grasped by an end effector of the robot system and the second layer is arranged to adhere to the item. A system having an affordance and a robot system with an end effector arranged to grasp at least one item from storage by way of the affordance is also disclosed.

According to an embodiment, an compressed air-based autonomous power generation system for a standalone industrial robot jig comprises an air compressor configured to supply compressed air, a compressed air-based power generator detachably connected with the air compressor to produce power and deliver the compressed air, an industrial robot jig connected with the compressed air-based power generator to receive the compressed air and clamp a product, a battery connected with the compressed air-based power generator to receive, and be charged with, the power, and to supply the power to the industrial robot jig, and an auxiliary air tank connected with the compressed air-based power generator to store the compressed air.

An object manipulation apparatus according to an embodiment of the present disclosure includes a memory and a hardware processor coupled to the memory. The hardware processor is configured to: calculate, based on an image in which one or more objects to be grasped are contained, an evaluation value of a first behavior manner of grasping the one or more objects; generate information representing a second behavior manner based on the image and a plurality of evaluation values of the first behavior manner; and control actuation of grasping the object to be grasped in accordance with the information being generated.